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SYLLABUS
M.Sc. (HON'S) BIOTECHNOLOGY PART-II
(SEMESTER III & IV)
Session 2016-17 continued for Session 2017-18
The course will consist of two semesters in the second year i.e., semester III and IV. In
semester III, there shall be four theory papers and two practical papers. In the semester IV,
there shall be two theory papers and one practical paper. In addition, the students shall
undertake project on research/industrial problems relevant to industrial biotechnology. The
in-plant training of 4-6 weeks shall be undertaken by students at various
industries/institutes/R&D centres, etc. after completion of theory and practical examinations
of semester II, which will be evaluated during the semesters III and IV.
Each theory paper shall have 5 hours teaching and 3 practical hours per week. Each theory
paper shall be of 100 marks, of which 75 marks shall be allocated to the theory paper set by
external examiner. The internal assessment in each paper shall have 25 marks, including a
seminar and an assignment of 5 marks each and 5 marks shall be given for the attendance of
the student. There shall be two tests of 10 marks each and average of the two tests shall be
considered. The seminars will be allotted to all the students from the respective syllabi of
theory papers in such a way that each student could be assessed by the teacher of the
concerned subject. The awards of internal assessment shall be dispatched by the Head of the
department before the commencement of semester examinations.
The subjects and distribution of marks shall be as under:
SEMESTER III
Theory Papers
Paper IX: Enzymology and Enzyme Technology 100 marks
Paper X: Food Biotechnology 100 marks
Paper XI: Advances in Environmental Biotechnology 100 marks
Paper XII: Entrepreneurship and Legal Biotechnology 100 marks
Practical Papers
Practical Paper V: Pertaining to Theory Paper IX & X 100 marks
Practical Paper VI: Pertaining to Theory Paper XI & XII 100 marks
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SEMESTER IV
Theory Papers
Paper XIII: Animal and Plant Tissue Culture Technology 100 marks
Paper XIV: Computational Biology and Applied Bioinformatics 100 marks
Practical Papers
Practical Paper VII: Pertaining to Theory Paper XIII & XIV 100 marks
Total marks for M.Sc.-II shall be as under:
SEMESTER III
Theory Papers (4) 400 marks
Practical Papers (2) 200 marks
Total 600 marks
SEMESTER IV
Theory Papers (2) 200 marks
Practical Papers (1) 100 marks
Industrial Visits, In-plant Training Seminars and Project Work Satisfactory/ Unsatisfactory
(Fail)
Total 300 marks
Grand Total (Semester III & Semester IV) 900 marks
Evaluation and viva-voce of project work will be conducted by one examiner. In-plant
training seminar and industrial visits shall be evaluated by a board of three teachers and
communicated by Head of department before commencement of final examinations.
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SEMESTER III
PAPER IX: ENZYMOLOGY AND ENZYME TECHNOLOGY
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION-A
1. Enzymes: Structure (folded conformations, active site geometry and 3D forms),
evolution (convergent and divergent) and its basis.
2. Enzyme action: Specificity, molecular aspects of enzyme action (theories and
kinetics), and examples from different classes of enzyme.
3. Regulation of enzymic action: Activation of enzymes, covalent modification,
allosteric interaction, multienzyme complexes.
4. Industrial production of enzymes: Sources of enzymes, criteria for the selection of
source for enzyme production, methods of large scale production-solid substrate
fermentation and submerged fermentation, factors affecting enzyme production,
amylases, cellulases, pectinases, lactases, invertases, lipases, proteases.
5. Immobilization of biocatalysts: Definition, objectives and advantages of
immobilization; techniques of immobilization, matrices - types, advantages and
limitations; Kinetic characterization of immobilized biocatalysts; concept of co-
immobilization.
6. Nanobiotechnology: Functionalization of enzymes, types of nanomaterials, mode of
interaction and application in food, bioenergy and pharma sector.
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SECTION-B
7. Biochemical applications: Role of soluble and immobilized enzymes in the synthesis
and production of amino acids and chiral compounds; use of enzymes as detergents.
8. Pharmaceuticals: Role of soluble and immobilized enzymes in production of
antibiotics, steroids, and other important intermediates of biotechnological industry;
role of soluble and immobilized enzymes in diagnosis and treatment of diseases;
enzyme therapy.
9. Applications in food industry: Soluble and immobilized enzymes - food production
and processing, amylases, pectinases, proteases, lipases, glucoisomerases, naringinase.
10. Analytical applications: Theory and applications of various enzyme electrodes e.g.
enzyme sensors, enzyme membranes, biochips/bio-semiconductors.
11. Enzyme engineering: In vitro approaches to improve functional efficiency;
Recombinant enzymes: Overexpression and applications.
12. Enzymes in organic solvents/ILs (Ionic liquids): Modes of using enzymes,
fundamentals and new properties.
RECOMMENDED READING
1. Fundamentals of Enzymology: The cell and Molecular Biology of Catalytic Proteins
by N.C. Price and L. Stevens, Oxford University, 2000.
2. Enzymolgoy Lab Fax by P.C. Engel, Academic Press, 2003.
3. Enzyme Structure and Function by A, Fersht, W.H. Freeman and Co., NY, 1999.
4. Enzymes, Biomass, Food and Feed (Biotechnology 2E, Vol. 9) by Rehm, Reed, and A.
Phuler, Wiley-VCH, Berlin, 2001.
5. Enzyme Kinetics: Principles and Methods by H. Bisswanger and L. Bubenheim, April
2002.
6. Industrial Enzymology: The Application of Enzymes in Industry by T. Godfrey and S.
May, McMillan publishers, 2001.
7. Enzyme Technology by M.F. Chaplin and C. Bucke, Cmabrigde University Press, NY,
1990.
8. Enzymes in Food Processing by G.A. Tucker and L.F.J. Woods.
9. Manual of Industrial Microbiology and Biotechnology by A.L Demain and N.A
Soloman, American Society for Microbiology, USA, 2003.
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10. A Textbook of Industrial Microbiology by W. Cruger and A. Cruger, Sinauer
Associates, USA, 2004.
11. Enzymatic Reactions in Organic Media by M.N. Gupta, Birkhauser Verlag
publication, 2000.
12. Supramolecular Enzyme Organization Quaternary Structure and Beyond by Peter
Friedrick, Pregamon Press, Oxford, 1994.
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PAPER X: FOOD BIOTECHNOLOGY
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION – A
1. Microorganisms for food and feed: Algal, bacterial, fungal and yeast biomass as
single cell protein; Solid-state fermentations and submerged fermentation
technologies for the production of SCP.
2. Baker’s yeast production and bread making: Morphology and physiology, production,
handling and harvesting of baker’s yeast; Production technology of bread.
3. Probiotic, prebiotic and functional foods: Concepts and applications in food;
Functional foods (oat products, milk and dairy products, sea food products);
Biopreservatives - A brief account.
4. Production of alcoholic beverages: Raw materials, culture, fermentation technology
and post fermentation processing of beer, wine, whiskey, vodka, rum and brandy.
5. Production of vinegar: Raw materials, culture and fermentation conditions, post
fermentation processing, recovery and applications.
6. Organic acids: Fermentative production and applications of citric acid and lactic acid;
Lactic acid fermented foods – A brief account.
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SECTION – B
7. Indian fermented foods and sugar syrups: Brief account of fermented foods (Vada,
Dosa, Warries, Marchu, Gundruk, Kimchi, Koji, Tempeh, Sauerkraut, Soya sauce).
8. Fermented dairy products: Production of cheese, cultured dairy milk, cultured cream,
yoghurt and kefir.
9. Microbial colours & flavours: Current status and future perspectives; Sugar syrups -
glucose syrup, invert syrup, high fructose syrup, maltose syrup.
10. Immobilized whole cell technology in food industry: Brief account in wine, beer &
dairy industry.
11. Waste utilization: Technology for the utilization of waste from dairy, fruit and
vegetable processing industries.
12. Food regulations: Brief account on FSSA 2006, FAO, FDA, AGMARK, HACCP,
CODEX ALIMENTARIUS.
RECOMMENDED READING
1. Biotechnology by R.H. Rehm and G. Reed (Vol. 4, 5, 6 and 7a), Verlag Press, NY,
1982 and 1987.
2. Biotechnology, Principles and Applications by J. Higgins, D.J. Bestand and J. Jones,
Blackwell Scientific Publications, London, 1985.
3. Biotechnology: Food Fermentation Technology by V.K. Joshi and A. Pandey,
Educational Publishers and Distributers, New Delhi, 1997.
4. Comprehensive Biotechnology by M. Moo Young (Vol. 3 and 4), Pergamon Press,
NY, 1985.
5. Essays in Applied Microbiology by J.R. Norris and M. H. Richmong, John Wiley and
Sons, NY, 1981.
6. Fundamentals of Biotechnology by P. Praive, B. Fraust, W. Sitting and D.A. Sukatesh,
VCH, Weinheim, 1987.
7. Microbial Biotechnology, Fundamentals of Applied Microbiology by A.N. Glazerand,
H. Nikaido, W.H. Freeman and Co., NY, 1995.
8. Prescott and Dunn’s Industrial Microbiology by B. Reed McMillan Publishers Ltd.,
Connecticut, 1982.
9. Principles of Fermentation Technology by P.F. Stanbury, A. Whitaker and J. Hall,
Pergamon Press, NY, 1984.
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10. Yeast Biotechnology by D.R. Berry, I. Russel and G.G. Stewart, Allen and Unwin,
Boston, 1987.
11. Food Biotechnology: Principles and Practices by V.K. Joshi and R.S. Singh, IK
International Publishers Pvt. Ltd., New Delhi, 2012.
12. Handbook of Enology: Principles and Practices by V.K. Joshi, Asiatech Publishers
Inc., New Delhi, 2011.
13. Biotechnology: Food Fermentation Microbiology, biochemistry and Technology by
V.K. Joshi & A.K. Pandey, Asiatech Publishers Inc., New Delhi, 2009.
14. Food Fermentation Biotechnology by A.K. Pandey, C.R. Soccol and C. Larroche,
Asiatech Publishers Inc., New Delhi, 2011.
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PAPER- XI: ADVANCES IN ENVIRONMENTAL BIOTECHNOLOGY
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION – A
1. Environmental pollution: effects and bioassays for analysis of pollutants: Introduction
to environment and environmental pollution, classification of pollutants, biochemical
and physiological effects of pollutants on plants, animals and microbes; types of
toxicity, biological indicators of pollution: enzymatic, microbial, algal, plant and
animal systems
2. Waste water treatment processes: primary, secondary and tertiary treatment of
municipal wastewater: theory and applications: physical treatment, chemical
treatment, precipitation: hot and cold soda lime process, disinfection: chlorination,
ozonization, UV treatment, demineralization-ion exchange by synthetic resins and
zeolites, reverse osmosis, filtration; advanced wastewater treatment: nutrient removal-
nitrogen and phosphorus removal
3. Engineered systems for aerobic wastewater treatment and disposal: primary treatment;
secondary treatment: suspended culture system-activated sludge (completely mixed
and plug flow reactors, process variations), ponds and lagoons, attached culture
system-trickling filters, biotowers and rotating biological contactors; mechanism of
aerobic biodegradation; factors affecting process operation; derivation of Monod’s
equation for suspended and attached culture systems
4. Anaerobic technologies for waste treatment: anaerobic decomposition, anaerobic filter
reactor, anaerobic contact reactor, fluidized bed reactor, up-flow anaerobic sludge
blanket, anaerobic baffled reactor, mechanism of anaerobic degradation, factors
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affecting process operation; biogas generation-raw materials, biochemistry and
microbiology, factors affecting biogas production and its status in India
5. Treatment of waste air: removal of particulate and gaseous contaminants; biological
technologies of waste air treatment, biological deodorization: bioscrubbers, biotowers,
bioventing
6. Environmental applications of biotechnology: microbial enhanced oil recovery;
treatment of wastewater of brewery, pharmaceutical, textile dyeing, metal processing,
petrochemical, pulp and paper industry; role of natural/stimulated, dead/spent
microbial cultures, GMOs and mushrooms in biological degradation processes,
phytoremediation
SECTION – B
7. Solid waste management: sludge treatment and disposal: characteristics, thickening,
digestion and disposal; land based treatment systems, landfilling, deep well injection,
composting and vermicomposting-PUSA vermicomposting, requirements and
preparation of vermicompost, nutrient comparison with ordinary and farmyard
manure, Indian scenario of vermicomposting; treatment of hazardous and medical
waste
8. Biomineralization and biohydrometalurgy: heavy metal tolerance, metal-microbe
interactions, genetic aspects of heavy metal resistance; biomineralization: mechanism
of heavy metal ion deposition; biohydrometallurgy and bioleaching of metals (copper
and uranium)
9. Bioaccumulation and bioremediation of pesticides: bioremediation-in situ and ex situ,
bioaugmenting; characteristics and types of xenobiotics, relationship of
bioaccumulation with chemical structure, bioaccumulation of toxicants: uptake
kinetics, factors affecting bioaccumulation; metabolic pathways and enzymes for
bioremediation of organo chlorinated, organo phosphorous and carbamate pesticides;
biotechnological applications for pesticide waste disposal
10. Biosensors: Birth of biosensor, advantages and disadvantages, immobilization of
biocomponent, tailored biocomponent for specific use, protein engineering for
construction of generic biosensors; Transducers - piezoelectric, potentiometric,
amperometric and fiber optics.
11. Specialized biosensors: Urea biosensor electrochemical and optical to check milk
adulteration; Heavy metal ions biosensor - whole cell, recombinant whole cell,
enzyme, apoenzyme, antibodies and DNAZyme nanoparticles based biosensors;
Pesticide biosensors: Antibodies quantum dots, enzyme and microbial biosensors,
nanobiosensors.
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12. Pathogen and BOD biosensors: SPR, potentiometric and amperometric pathogen
biosensors and comparison with conventional methods; BOD biosensors - Principle of
DO probe, bacterial and yeast BOD biosensors.
RECOMMENDED READING
1. A Text Book of Biotechnology by R.C. Dubey., S. Chand & Company Ltd., New Delhi,
2002.
2. Advances in Industrial Waste Water Treatment by P.K. Goel, Technoscience
Publications, 1999.
3. An Introduction to Molecular Ecology by T. Beebee and G. Rowe, Oxford University
Press, New Delhi, 2004.
4. Basic Environmental Science by G.S.P. Iyer, Educational Publishers and Distributers,
New Delhi, 1997.
5. Biotechnological Applications in Environment and Agriculture, by P.K. Goel and G.R.
Pathade, ABD Publishers, Jaipur, 2004.
6. Biotechnology-Applications to Environmental Protection by M.M. Pandey, Himalaya
Publishing House, 1993.
7. Clean Technology and the Environment by R.C. Kirkwood and A.J. Longley, Blackie
Academy and Professional, 1995.
8. Commercial Biotechnology, Elsevier Science Publishers B.V., Amsterden, The
Newdesk, 1984.
9. Comprehensive Biotechnology by M. Moo-Young (Vol. 4), Pergamon Press, New
York, 1985.
10. Environmental Biotechnology (Industrial pollution management Edition) by S.N.
Jogdand, Third Revised Edition, 2006.
11. Environmental Biotechnology and Cleaner Bioprocesses by E.J. Olguin, G. Sanchez
and E. Hernandez, Taylor and Francis Inc., 2003.
12. Environmental Biotechnology, Basic concepts and Application by I.S. Thakur, 2006.
13. Environmental Biotechnology by M.H. Fulekar, I.B.H Publishing Co. Pvt. Ltd, New
Delhi, 2005.
14. Environmental Engineering by H.S. Peavy, D.R. Rowe and G. Tchobanoglous, Mc
Graw Hill International Edition, 1988.
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15. Environmental Modeling Fate and Transport of Pollutants in Water, Air and Soil by
J.L. Schnoor, Wiley Interscience Publication Ltd., NY, 1996.
16. Environmental Molecular Microbiology: Protocols and Applications by P.A.
Rochelle, Horizon Scientific Press, 2001.
17. Environmental Science and Biotechnology: Theory and Techniques by A.G.
Murugesan and C. Rajakumari, MJP Publishers, Chennai, 2006.
18. Environmental Science by W.P. Cunningham and B. Woodworth, WCB/McGraw
Saigo Hill, 1999.
19. Industrial Water Pollution Control, W.W. Elbenfields-jr., Mc Graw Hill International
Editions, 1998.
20. Instant Notes in Ecology by A. Mackenzie, A.S. Ball and S.R. Virdee, Bios Scientific
Publishers Ltd., UK, 1999.
21. Introduction to Environmental Technology by A.K. Chatterji, Prentice Hall of India
Pvt. Ltd., New Delhi, 2002.
22. Methods in Environment Analysis: Water, Soil and Air by P.K. Gupta, Agrobios,
India, 2007.
23. Microenvironment and Metabolic Compartmentation by P.A. Sreri and R.W.
Estabrook, Academic Press Inc., New Delhi, 1978.
24. Pesticide Properties in the Environment by A.G. Hornsky, R.D. Wauchope and A.E.
Herner, Springer-Verlag, New York Inc., 1996.
25. Popular Biotechnology Lecture Series Focus: Bioremediation by Division of
Biotechnology, PSCST, 2013.
26. Protein Immobilization: Fundamentals and Applications by R.F. Taylor, 1991.
27. Text Book of Environmental Biotechnology by P.K. Mohapatra, I.K. International
Publishing House Pvt. Ltd., New Delhi, 2006.
28. Toxic Substances in the Environment by B.M. Francis, Wiley Interscience Publication
Ltd., NY, 1994.
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PAPER XII: ENTREPRENEURSHIP AND LEGAL BIOTECHNOLOGY
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION-A
1. Scope and status of biotechnology in India and globally.
2. Biotechnology development assistance: Government programmes, International
organizations, University- Industry Relationship.
3. Biosafety: Introduction Biohazards, Department of Biotechnology Biosafety
Guidelines 1990, IGMORIS, Cartagena Protocol, Guidelines on Biosimilars 2012.
4. Intellectual property rights: Intellectual property, types and related Indian legislations;
WIPO, International conventions - TRIPs Agreement, PCT, Paris convention,
Budapest treaty; Trade secret protection, preparation and preservation of invention
records.
5. Patents: Patentable subject matter; Patentability criteria - Novelty, inventiveness and
industrial application; Prior art; Provisional and complete specifications; Patent
claims.
6. Patenting systems: Types of patent applications, National (India) and International
patent filing, patent infringement; Patentability of biological processes and products
in India; Patent search – databases.
SECTION-B
7. Total quality management: Introduction and concept, cost and economics of quality,
tools and techniques for analyzing the quality process, six-sigma.
8. Strategic management: Fundamentals of management, strategic management
framework for science and technology organizations, SWOT analysis.
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9. Technology commercialization: Process of commercialization of technologies from
academic institutions- models, the role of technology incubators, the Bayh Dole Act,
technology commercialization policy initiatives in India.
10. International organization for standardization (ISO): About the organization and its
functioning, members, relevance of certification; Introduction to GMP certification.
11. ISO certification: ISO 9000:2008 & ISO 14000:2004, members and requirements.
12. Entrepreneurship: Concept of entrepreneurship, entrepreneurial characteristics,
entrepreneurial motivation and barriers, classification of small, medium and large
scale industries, feasibility study, project planning, fund management, marketing mix.
RECOMMENDED READING
1. Bare Act, Indian Patent Act 1970 Acts & Rules, Universal Law Pubs. Ltd., 2013.
2. Biotech Innovations and Fundamental Rights by R. Bin, S. Lorenzon and N. Lucchi,
Springer, 2012.
3. Entrepreneurial Development by S.S. Khanks, S. Chand and Company, New Delhi,
1999.
4. Entrepreneurship by T.W. Zimmer and N.M. Scarborough, Prentice Hall, New Jersey,
USA, 1996.
5. Entrepreneurship Strategies and Resources by M.J. Dollinger, Prentice Hall, Upper
Saddal River, USA, 1999.
6. Genetic Patent Law & Strategy by C. Kankanala, Manupatra Information Solution Pvt.
Ltd., 2007.
7. Globalising Intellectual Property Rights: The TRIPS Agreement by D. Matthews,
Routledge, 2004
8. Guide to Quality Management Systems for the Food Industry by R. Early, Blackie
Academic, NY, 1995.
9. Intellectual Property Law by Davis, Jennifer, Butterworth’s, London, 2001.
10. Intellectual Property Rights on Biotechnology by K.C. Singh, BCIL, New Delhi, 2004.
11. Intellectual Property Rights: Patent Laws in India by G.V. Rao, SSDN Publishers,
2013.
12. Intellectual Property Rights: Innovation, Governance and the Institutional
Environment by I. Andersen, Edward Elgar Publs, 2006.
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13. Intellectual Property: Patents, Trade Marks and Allied Rights by W.R. Cornish,
Universal Law Publishing, Delhi, 2001.
14. ISO 14000:2004- BIS publication
15. ISO 9000:2008- BIS publication
16. Law of Intellectual Property by S.R. Myneni, Asia Law House, Hyderabad, 2001.
17. Patenting Lives: Life Patents, Culture and Development by J. Gibso, Ashgate Publs,
2008.
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PRACTICAL PAPER V
Pertaining to:
Theory paper IX: Enzymology and Enzyme Technology
Theory paper X: Food Biotechnology Pass Marks: 40%
Max. Marks: 100 Practical Time: 60 hours
Time: 4 hours
1. Standardization and optimization of immobilization techniques for enzymes and cells.
2. Comparative kinetic characterization of soluble/free and immobilized enzymes/cells.
3. Production of enzymes at laboratory scale - α-amylase, inulinase, aspartase, pectinase
etc.
4. Demonstration of activities of soluble and immobilized enzymes - invertase, α-
amylase, inulinase, aspartase, pectinases and naringinase.
5. Fabrication of enzyme sensors and demonstrations of their functions.
6. Enzymatic preparation of high fructose syrup and maltose syrup.
7. Utilization of fermentation industry waste.
8. Preparation of Indian fermented foods.
9. Production of lactic acid fermented food.
10. Preparation of fermented dairy products.
11. Biopreservation of food.
12. Extraction of microbial pigments.
13. Production of baker’s yeast and evaluation of its leavening effect.
14. Production of fructooligosaccharides.
15. Production of organic acids.
16. Production of various types of wines using free and immobilized cells.
17. Production and evaluation of single cell protein-fungal and yeast biomass.
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PRACTICAL PAPER VI
Pertaining to:
Theory paper XI: Advanced Environmental Biotechnology
Theory paper XII: Entrepreneurship & Legal Biotechnology Pass Marks: 40%
Max. Marks: 100 Practical Time: 60 hours
Time: 4 hours
1. Adulteration check in milk by Urea Biosensor
2. Biogas production monitoring by gas chromatography.
3. Bioremediation of heavy metal ions
4. Bioremediation of heavy metal laden (Ni+2) industrial effluent by immobilized
cyanobacteria through packed bed reactor.
5. Bioremediation of pesticides.
6. Bioresin for treatment of chromium-laden effluents.
7. Calibration of DO Probe.
8. Calibration of ISE Electrode.
9. Characterization of industrial effluents for pH, TS, TDS, TSS, acidity, alkalinity and
hardness parameters.
10. Co-Immobilization of enzyme and indicator dye for construction of Biosensor.
11. Demonstration of biogas production from industrial effluents using batch and
anaerobic baffled reactors.
12. Demonstration of vermicompost and landfill technologies.
13. Detection of pesticides by HPLC method.
14. Determination of chemical oxygen demand (COD) in various effluents.
15. Determination of chromium content in a given industrial sample.
16. Determination of heavy metal ions in industrial effluents by Atomic absorption
spectrophotometer and spectrophotometric methods.
17. Development of biosensor (enzyme based/ microbe based) for monitoring heavy
metal ions in the environment.
18. Development of biosensor (enzyme based/ microbe based) for monitoring pesticides
in the environment.
19. Development of BOD Biosensor
20. Evaluation of Biochemical Oxygen Demand (BOD) in various effluents.
21. Heavy metal decontamination of effluents by microbial systems.
22. Isolation of microbial consortia from fermentation industry.
23. Microbial degradation of heavy metal ions by free cell and immobilized systems.
24. Microbial degradation of pesticides.
25. Microbial degradation of textile dyes by free cell and immobilized systems.
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26. Microbial degradation of xenobiotics.
27. Microbiological analysis of waste water.
28. Production of bioalcohol from agricultural, dairy and food waste.
29. To demonstrate the development of a small-scale vermicomposting bin for
commercialization
30. Overview of IP office websites: India, USA.
31. Overview of patent databases.
32. National patent search: Indian patents
33. International patent search on US patents and EPO patents.
34. Overview of ISO`s official website
35. Study of implementation of ISO standards in a concern
36. An over view of ISO 9000 family of quality management standards.
37. A brief about ISO 9000 certified Indian companies.
38. An overview of ISO 14000 family of environment management standards.
39. A brief about ISO 14000 certified Indian companies.
40. A brief about ISO 22000 certified Indian companies.
41. Overview of biotechnology industries in Punjab.
42. Overview of biotechnology industries in India.
43. Use of MS-Office software to sketch a company profile.
44. To identify the TQM related problems in an organization and to give a possible
solution.
45. To study the essential elements of TQM.
46. Internet Survey of Biotechnology Industries Globally.
47. Internet Survey of Biotechnology Industries of India
48. Data retrieval from IGMORIS site pertaining to Genetically Modified LMOs.
49. Designs of Biosafety Lab Level I,II, III and IV.
50. Internet Survey of BIO, FDA and WHO pertaining to GMOs.
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SEMESTER IV
PAPER XIII: ANIMAL AND PLANT TISSUE CULTURE TECHNOLOGY
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION-A
1. Plant tissue culture: Introduction and history, scope and applications, culture room
and vessels, medium constitution and functions of each element, growth regulators,
sterilization techniques; Setting up of primary culture.
2. Callus: Formation, cloning, suspension culture, regeneration.
3. Somatic embryogenesis: Factors and molecular aspects; Micropropagation; Raising of
virus free and pest resistant plants, methods.
4. Germplasm conservation: Cryopreservation methods, slow growth, applications and
limitations.
5. Haploid production: Androgenesis, gynogenesis, embryo rescue, somatic
hybridization, proroplast isolation, fusion and selection of hybrids; Application;
Cybrids formation.
6. Somaclonal variation, plant transformation techniques; Secondary metabolites.
SECTION-B
7. Animal cell culture: Historical background, scope, biology of cultured cell, media
composition, preparation, sterilization techniques for ATC lab and maintenance of
contamination free conditions.
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8. Animal cell lines: Types of cell lines (Monolayer and suspension cultures); Setting up
of primary culture - Disaggreagation methods and cell line kinetics, properties;
Maintenance of cell line - subculture, viability testing, treatment of substratum, feeder
layers.
9. Scale up of monolayer and suspension cultures: Scale up of monolayer culture -
NUNC cell factories, multi array disk, roller culture, perfused monolayer culture;
Scale up of suspension cultures - stirrer or spinner culture; Bioreactors – wave
bioreactor, biostat, rotating chambers, airlift fermenter, fluidized bed reactor, hollow
fiber, perfused, NASA bioreactor; Differentiation inducers, characterization of cell
lines.
10. Somatic cell fusion: Monoclonal antibody formation, culture of tumor cells; Cloning
of cultured cells – methods.
11. Animal cloning: Superovulation, embryogenesis, in vitro fertilization; Stem cells
technology: Culture, characteristics.
12. Applications: Industrial applications of ATC; Stem cell applications; Mammalian cell
products applications – monoclonal antibodies, vaccines, therapeutic, recombinant
glycoproteins from mammalian cells, tissue engineering, cells as products.
RECOMMENDED READING
1. Plant Tissue Culture and Molecular Biology by P.S. Srivastava, N.R. Book
Distributors, New Delhi, 1998.
2. Genetic Transformation in Plants by R. Walden, Open University Press, Buchingham,
1988.
3. Animal Cell Culture Technology by M. Buttler, Open University Press, Buchingham,
1987.
4. Animal Cell Culture by R.I. Freshney, A.R. Liss Inc., New York, 1989.
5. Plant Cell Culture by H.A. Collins, NR Book Distributors, New Delhi, 1998.
6. Plant Tissue Culture-Theory and Practice by S.S. Bhojwani and M.K. Razdan,
Prentice Elsevier, London, 1983.
7. Plant Tissue Culture Methods - Applications in Agriculture by J. Reinart and Y.P.S.
Bajaj, Springer - Verlag, Berlin, 1989.
8. Plant Cell, Tissue and Organ Culture by J. Reinart and Y.P.S. Bajaj, Narosa
Publication House, New Delhi, 1989.
9. Principles of Plant Biotechnology by H. Maitell, J. Mathew and R.A. Mackee,
Blackwell Scientific Publishers, Oxford, 1985.
21
10. Plant Cell Culture Technology by M.M. Yoeman, Blackwell Scientific Publication,
Oxford, 1986.
11. Plant Cell Culture by A. Stanford and G. Warren, Open University Press,
Buchinghum, 1990.
12. Plant Cell and Tissue Culture A Laboratory Manual by J. Reinart and M.M. Yoeman,
Narosa Publishing House, New Delhi, 1982.
22
PAPER XIV: COMPUTATIONAL BIOLOGY AND APPLIED BIONIFORMATICS
Maximum Marks: 75 Lectures to be delivered: 60
Time Allowed: 3 Hours Pass Marks: 40% (Theory and
Practical separately)
INSTRUCTIONS FOR THE PAPER-SETTER
The question paper will consist of three sections A, B and C. Section A and B will have four
questions from the respective sections of the syllabus and carry 15 marks each. Section C will
consist of 10 short answer type questions which will cover the entire syllabus uniformly and
will carry 15 marks in all.
INSTRUCTIONS FOR THE CANDIDATES
1. Candidates are required to attempt two questions each from sections A and B of the
question paper and the entire section C.
2. The use of scientific calculators is allowed.
SECTION – A
1. Bioinformatics and computational biology: Definition, applications in scientific
research, present bioinformatics scenario in India; Open access computational and
bibliographic resources related to Life Sciences viz., NCBI, EBI, EXPASY,
EMBOSS, PubMed Central.
2. Nucleotide sequence databases: Characteristics and categories of biological databases,
navigating databases; Organization of databases - data contents and formats of data
entries, purpose and utility in life sciences, the knowledge of various computational
tools available at these resources - INSDC, Genbank, EMBL, DDBL; Microbial
genome databases with special reference to model organisms (E. coli, Yeast).
3. Protein sequence, structure and interaction databases: Characteristics and categories
of biological databases, navigating databases; Organization of databases - data
contents and formats of data entries, purpose and utility in life sciences, the
knowledge of various computational tools available at these resources: protein
sequence databases - IPSDC, Swiss-Prot, PIR-PSD, UniProt-KB; Protein structure
databases - PDB; Protein structure classification databases - CATH, SCOP; Protein
family classification - PROSITE, Pfam; Protein-protein interaction database –
STRING.
4. Specialized and composite databases: Composition, organization and format of data
entry; Diseases database (OMIM), metabolic pathways (KEGG), enzymes
(BRENDA); Composite databases: OWL, BIOSILICO.
23
5. Information retrieval and data submission systems: Keyword-based and advanced
searches using tools like ENTREZ and SRS; Sequence submission using BankIt,
Sequin, WebIn, Spin (Swiss-Prot).
6. Substitution matrices algorithms for scoring sequence alignments: PAM matrix
construction algorithm, BLOSUM matrix construction algorithm; Nucleic acid
substitution matrices; Use of gaps and gap penalties.
SECTION – B
7. Algorithms of sequence comparison: Definition, dynamic programming; dot plots;
Sequence comparison algorithms: Pairwise comparison, global sequence alignment
algorithm (Needleman Wunsch algorithm), local sequence alignment algorithm
(Smith Waterman algorithm), semi-global algorithm.
8. Pairwise sequence alignment: Basic concepts of sequence similarity, identity and
homology, definitions of homologues, orthologues, paralogues; Types and
applications of BLAST and FASTA, statistical significance of scores; Nucleic acid
sequence analysis - pairwise alignment, ORF and restriction analysis, sequence
translation; Protein sequence analysis - pairwise alignment, peptide cleavage analysis,
prediction of transmembrane proteins, in silico analysis of protein modifications,
reverse translation.
9. Genome analysis using pairwise sequence alignment: Overview of web resources for
genome information and analysis; Gene identification methods (GENSCAN, GRAIL).
10. Multiple sequence alignment and phylogenetic analysis: Multiple sequence alignment
tools - clustalW, its application for sequence analysis (including interpretation of
results), concept of dandrogram and its interpretation; Relationship of phylogenetic
analysis and sequence alignment, overview of phylogenetic analysis methods;
Distance scores; Tree confidence - bootstrapping, parametric tests; Analysis tools -
Phylip, Phyml.
11. Prediction of protein secondary structure: Chow-Fasman/GOR method, secondary
structure prediction by Neural Network (NNSSP), analysis of results and measuring
the accuracy of predictions; Viewing protein structures and 2D modeling: RASMOL,
CHIME.
12. Prediction of protein 3D structure: Fundamentals of the methods for 3D structure
prediction (sequence similarity/identity of target proteins of known structure,
fundamental principles of protein folding, etc.), homology/comparative modeling,
fold recognition, threading approaches, and ab initio structure prediction methods; 3D
modeling: DeepView (SwissPDB viewer).
24
RECOMMENDED READING
1. Bioinformatics: Sequence and Genome Analysis by D.W Mount, Cold Spring Harbor
Press, NY, 2001.
2. Introduction to Bioinformatics by T.K Attwood and D.J. Perry-Smith), Pearson
Education Ltd., 1999.
3. Bioinformatics: Sequence, Structure and Databanks by D. Higgins and W. Taylor,
Oxford University Press, UK, 2000.
4. Introduction to Bioinformatics by A.M. Lesk, Oxford University Press, UK, 2005.
5. Practical Bioinformatics by J.M. Bujnieki, Springer-Verlag Berlin, Heidelberg, 2004.
6. Bioinformatics and Molecular Evaluation by P.G. Higgs, Blackwell Publishing
Company, 2005.
7. Algorithms in Bioinformatics by G. Benson and R. Page, Springer-Verlag, Germany,
2004.
8. Bioinformatics Basics: Applications in Biological Science & Medicine by L.K.
Buehler and H.H. Rashidi, Taylor and Francis Group, 2005.
9. Biological Sequence Analysis: Probabilistic Models of Protein and Nucleic Acids by
Durbin et al., Cambridge University Press, UK, 2007.
10. Proteins: Structures and Molecular Properties by T.E. Creighton, W.H. Freeman,
1992.
11. Fundamental Concepts of Bioinformatics by D.E. Krane and M.L. Raymer, Pearson
Education Inc., 2003.
12. Structural Bioinformatics by P.E. Bourne and H. Weissig, Wiley-Blackwell
Publishers, 2003.
13. Methods in Molecular Biology, (volume 132; Bioinformatics: Methods and Protocols)
by S. Misener and S.A. Krawetz, Humana Press Inc., 2000.
14. Bioinformatics: Databases, Tools and Algorithms by O. Bosu and S.K. Thukral,
Oxford University Press, UK, 2007.
15. Bioinformatics Methods and Applications-Genomics, Proteomics and Drug Discovery
by S.C. Rastogy, N. Mendiratta and P. Rastogi, Prentice Hall of India Pvt. Ltd., New
Delhi, 2004.
25
Practical Paper VII
Pertaining to:
Theory paper XIII: Animal and Plant Tissue Culture Technology
Theory paper XIV: Computational Biology and Applied Bioinformatics Pass Marks: 40%
Max. Marks: 100 Practical time: 60 Hours
Time: 4 hours
1. Lymphocyte and monolayer culture technique, viability testing and subculturing.
2. Animal cell quantitation.
3. Growth curve of mammalian cell line in culture and determination of cell doubling
time.
4. Orientation to a tissue culture facility.
5. Preparation of medium.
6. Callus initiation using an explant.
7. Callus subculturing from an established callus.
8. Micropropagation of provided plant material.
9. Introduction to hardening and biological hardening.
10. Open access computational and bibliographic resources related to Life Sciences viz.
NCBI, EBI, EXPASY, EMBOSS, PubMed Central
11. Keyword-based and advanced searches using tools like ENTREZ and SRS
12. Formats, querying and retrieval from GenBank, EMBL, DDBJ
13. Formats, querying and retrieval from Swiss-Prot, TrEMBL, PIR-PSD, UniProt-KB;
PDB; CATH, SCOP, Pfam, PROSITE; STRING
14. Formats, querying and retrieval from OMIM, KEGG, BRENDA; OWL, BIOSILICO
15. Genomes of model organisms (Yeast, E. coli)
16. Types and applications of BLAST
17. Types and applications of FASTA
18. Nucleic acid sequence analysis: pairwise alignment, ORF and restriction analysis,
sequence translation, gene prediction using GENSCAN, GRAIL
19. Protein sequence analysis: pairwise alignment, peptide cleavage analysis, prediction
of transmembrane proteins, in silico analysis of protein modifications, reverse
translation
20. Viewing protein structures and 2D modeling: RASMOL, CHIME
21. Protein 3D structure prediction
22. Phylogenetic analysis: Phylip, Phyml